Hybrid nucleic acid molecules and vectors including β-globin regulatory elements

ABSTRACT

The invention relates to hybrid nucleic acid molecules for gene therapy in cells of the erythroid lineage, and in particular α-, β-, δ-, ε, γ-, or ζ-globin nucleotide sequences operably linked to β-globin regulatory elements. The hybrid nucleic acid molecules, at single copy, are capable of producing a polypeptide. The hybrid nucleic acid molecules are useful for treatment of hemoglobinopathies such as sickle cell anemia or β-thalassemia. 
     The hybrid nucleic acid molecules are useful at single copy for erythroid expression at single copy of RNA and polypeptides in transgenic animals.

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority from Canadian application no. 2,246,005, filed on Oct. 1, 1998, which is incorporated by reference in its entirety.

FIELD OF THE INVENTION

The invention relates to hybrid nucleic acid molecules and vectors for expression, at single copy, of RNA, polypeptides and for gene therapy in erythroid and other cells. In particular, the invention relates to hybrid nucleic acid molecules and vectors that are useful for treatment of hemoglobinopathies such as sickle cell anemia and β- or α-thalassemia.

The invention also relates to hybrid nucleic acid molecules that are useful for erythroid expression at single copy of RNA and polypeptides in transgenic animals.

BACKGROUND OF THE INVENTION

One difficult aspect of gene therapy is in reproducibly obtaining high-level, tissue-specific, and long-term expression from nucleic acid molecules transferred into stem cells [1]. Since commonly used retrovirus and Adeno-Associated Virus (AAV) vectors may integrate at single copy, their transduced nucleic acid molecules should be regulated by tissue-specific elements that function at single copy. Locus Control Regions (LCR) are well suited for this task as they direct reproducible expression from all integration sites and transgene copy numbers[2], indicating that they have transcriptional enhancement and chromatin opening activities. For example, the human β-globin LCR directs high level β-globin transgene expression in erythroid cells of transgenic mice regardless of the integration site. However, it has become apparent that the β-globin LCR cannot confer reproducible transgene expression in mice on other nucleic acid molecule sequences such as the LacZ marker gene [3, 4], γ-globin genes [5-7], or even β-globin genes that lack a 3′ element [8, 9]. These findings suggest that chromatin opening by the LCR requires β-globin gene sequences, and that the utility of this LCR is limited to expression of the β-globin gene. It is not clear what gene sequences would be useful. In contrast to expression in transgenic mice, chromatin opening activities are not required for transient expression [4] or for stable expression when under selection for a drug resistance gene [10]. Therefore, such in vitro assays are not well suited for the evaluation of minigene cassettes for use in retrovirus-mediated gene therapy.

Efficient cell-specific nucleic acid molecule expression at some but not all transgene integration sites can be achieved by using cell-specific gene proximal elements including promoter elements, cell-specific regulatory elements such as enhancers and silencers, RNA processing signals, and cell-specific RNA-stabilizing elements. Cell-specific gene expression at all transgene integration sites primarily results from locus control regions (LCRs). However, it is considered to be very difficult to design a hybrid nucleic acid molecule that expresses at all integration sites for gene therapy of erythroid cells or their precursors because there is inadequate information about regulation of erythroid gene expression by LCRs and of the requirement by LCRs for specific gene proximal elements. Currently, no suitable hybrid nucleic acid molecule that expresses at single copy at all transgene integration sites for erythroid or precursor cell gene therapy has been reported.

SUMMARY OF THE INVENTION

The invention is a hybrid nucleic acid molecule for expressing RNA and polypeptides specifically in cells of the erythroid lineage. It is particularly useful for gene therapy of diseases such as thalassemias and sickle cell anemia by delivery of therapeutically useful globin proteins in erythroid cells. Other RNA and polypeptides may also be delivered with the hybrid nucleic acid molecules for gene therapy or in transgenic animals.

The invention uses human β-globin DNA regulatory elements to obtain high level, reproducible, tissue specific, single copy expression of coding nucleic acid molecules. Unlike past attempts to use β-globin DNA regulatory elements in preparing vectors, the invention uses much smaller portions of β-globin DNA regulatory elements. The simultaneous presence of the β-globin promoter, intron 2 and 3′ enhancer and the 5′HS3 is sufficient to provide coding nucleic acid molecule expression, for example the γ-globin gene. The hybrid nucleic acid molecule is suitable for DNA or viral mediated gene therapy of sickle cell anemias and thalassemias.

The invention also includes an isolated nucleic acid molecule comprising β-globin DNA regulatory elements that is capable of having a coding nucleic acid molecule inserted in it. The molecule is capable of directing production of a polypeptide at single copy in a targeted cell of the erythroid lineage.

In a preferred embodiment, the invention relates to hybrid nucleic acid molecules for gene therapy in erythroid and other cells, and in particular α-, β- δ-, ε-, γ-, or ζ-globin nucleotide sequences, or derivatives thereof, operably linked to β-globin regulatory elements. The hybrid nucleic acid molecules are useful for treatment of hemoglobinopathies such as sickle cell anemia or β- or α-thalassemia.

The invention also includes a hybrid nucleic acid molecule for producing a protein in a targeted cell, preferably an erythroid cell, consisting of:

β-globin DNA regulatory elements, and

a nucleic acid molecule operatively associated with the regulatory elements and capable of expression in the cell.

Other hemoglobinopathy or erythroid diseases, disorders or abnormal physical states that require erythroid specific expression may also be treated. They are useful for expressing any genes in cells of the erythroid lineage in mammals, such as mice or human, such as genes encoding Glucose 6 Phosphate Dehydrogenase or ferrochelatase polypeptides. Marker genes may also be used, such as green fluorescent protein.

In a preferred embodiment, the hybrid nucleic acid molecule consists of all or part of the nucleotide sequence of the BGT50 construct shown in FIG. 8. The β-globin DNA regulatory elements are preferably human β-globin DNA regulatory elements. The regulatory elements are preferably a 5′HS3, a promoter, a 3′ enhancer and intron 2.

The invention also includes a composition, preferably a pharmaceutical composition, including a therapeutically effective amount of the hybrid nucleic acid molecule and a pharmaceutically acceptable carrier. Another embodiment of the invention relates to a composition comprising the hybrid nucleic acid molecule and a carrier.

In another embodiment, the invention relates to the use of a hybrid nucleic acid molecule for treatment of a disease, disorder or abnormal physical state, including hemoglobinopathy. Another embodiment of the invention includes a method of medical treatment of hemoglobinopathy comprising administering a hybrid nucleic acid molecule to a patient and expressing the nucleic acid molecule.

The invention also includes a method of designing a hybrid nucleic acid molecule for treatment of a hemoglobinopathy. The method involves generating a series of hybrid nucleic acid molecules including erythroid cell-specific regulatory elements and then assessing each hybrid nucleic acid molecule single copy transgenic mice for the expression of reporter nucleic acid molecules or the hybrid nucleic acid molecule.

The invention includes a hybrid nucleic acid molecule for treating a defect in a globin gene in a cell of an erythroid lineage, the hybrid nucleic acid molecule including: a) β-globin gene regulatory elements which elements are capable of regulating gene expression in the cell; and b) a coding nucleic acid molecule operatively associated with the regulatory elements and capable of expression in the cell, the coding nucleic acid molecule encoding a globin protein or a derivative thereof having globin activity. The defect being treated causes a hemoglobinopathy. The target cell may be an erythroid cell. The invention also includes a cell of an erythroid lineage containing recombinant β-globin DNA regulatory elements and a coding nucleic acid molecule operatively associated with the regulatory elements, the cell expressing polypeptides, such as globins, not normally expressed by the cell at biologically significant levels.

Another aspect of the invention includes DNA sequences which are complementary to the aforementioned sequences.

Another embodiment of the invention relates to a hybrid nucleic acid molecule that at single copy is capable of producing a RNA and a polypeptide in a targeted mammalian cell of the erythroid lineage, including:

β-globin DNA regulatory elements, and

a coding nucleic acid molecule operatively associated with the regulatory elements and capable of expression in the cell.

The hybrid nucleic acid molecule CAN INCLUDE all or part of a nucleic acid molecule selected from th group consisting of

a) SEQ ID NO:1 or SEQ ID NO:2, or a complement thereof

b) SEQ ID NO:3 or SEQ ID NO:4, or a complement thereof

c) a nucleic acid molecule that hybridizes to all or part of a nucleic acid molecule shown in SEQ ID NO:1-SEQ ID NO:4, or a complement thereof under high stringency hybridization conditions; and

d) a nucleic acid molecule having at least 70% identity with the nucleotide sequence of (a) or (b).

The mammal is preferably a human. The β-globin DNA regulatory elements may include 5′HS3, a β-globin promoter, a β-globin intron 2 and a β-globin 3′ enhancer. In another embodiment the β-globin DNA regulatory elements may include an 5′HS3, Aγ-globin promoter, a β-globin intron 2 and a β-globin 3′ enhancer. The coding sequence preferably encodes a globin polypeptide or a derivative thereof having globin activity, such as α-, β-, δ-, ε-, γ- or ζ-globin. The β-globin DNA regulatory elements may include human β-globin DNA regulatory elements. The regulatory elements may include a 5′HS3, a promoter, a 3′ enhancer and intron 2.

The hybrid nucleic acid molecule preferably includes 5′-A-X-Y-C-D-3′ wherein A is a 5′HS3, X includes a β-globin promoter or an Aγ-globin promoter, Y includes a coding nucleic acid molecule, C includes a β-globin intron 2, and D includes a β-globin 3′ enhancer. The coding nucleic acid molecule preferably encodes a globin polypeptide or a derivative thereof having globin activity.

The invention also includes a vector including a nucleic acid molecule of the invention. The invention also includes a composition including a vector or nucleic acid molecule of the invention. Another aspect of the invention is a host cell including a vector or nucleic acid molecule of the invention. The host cell can include a cell of the erythroid lineage selected from the group including an erythroid cell, an erythroid cell precursor, a bone marrow cell, an umbilical cord blood cell, a hematopoietic stem cell, a hematopoietic stem cell that is CD34−/CD38−, or CD34+/CD38−, a progenitor cell of the erythroid lineage, CFU-GEMM, BFU-E, CFU-E, a pro-erythroblast, an erythroblast and an erythrocyte.

BRIEF DESCRIPTION OF THE DRAWINGS

Sequence identification numbers (SEQ ID NO;) in the figures refer to the 5′ to 3′ strand. Preferred embodiments of the invention will be described in relation to the drawings in which:

FIG. 1

5′HS3-linked β-globin, γ-globin, and β/γ-globin hybrid constructs used to determine which β-globin sequences are required by 5′HS3 to activate single-copy transgenes. RNA levels from each construct was analyzed in the fetal liver of 15.5 day single-copy transgenic founder mice. BGT9 was designed to determine if the 850 bp 5′HS3 fragment could activate single-copy β-globin transgenes. BGT26 was designed to determine if 5′HS3 could similarly activate single-copy γ-globin transgenes or whether a functional interaction between 5′HS3 and β-globin sequences was necessary for single-copy transgene activation. The series of β/γ-globin transgenes that follow were designed to illustrate which β-globin sequences are required for single-copy transgene activation by 5′HS3. βProm, β-globin promoter; γProm, γ-globin promoter; βivs2, β-globin intron 2; β3′enh, β-globin 3′ enhancer; MAR, matrix attachment region within β-globin intron 2.

FIG. 2

Expression of human globin mRNA in transgenic mice containing the BGT9 construct. S1 nuclease analysis on fetal liver RNA of 15.5 day F₀ BGT9 transgenic mice showing that BGT9 is expressed in all 17 animals including 3 single-copy mice. These data show that the 850 bp 5′HS3 element can express reproducible levels of β-globin transcripts. Hβ, human β-globin protected probe fragment; Mβ, mouse β major protected probe fragment; N, nontransgenic; μD, one copy μD14 microlocus line (discussed in text).

FIG. 3

Expression of human globin mRNA in transgenic mice containing the BGT26 and BGT34 constructs. S1 nuclease analysis on fetal liver RNA of 15.5 day F₀ transgenic mice showing that BGT26 is expressed to low or undetectable levels and that BGT34 is expressed to significant levels in 4/7 transgenic mice. These data show that β-globin gene sequences are required for reproducible single-copy transgene activation by 5′HS3 and that the β-globin promoter element is not sufficient for this activity. Hγ, human Aγ-globin protected probe fragment; Mβ, mouse β major protected probe fragment; N, nontransgenic; C, 50-48, the highest expressing BGT50 single-copy transgenic mouse (discussed in text; see FIG. 6); 3X, probe excess control. Copy #=1*, one intact copy plus a partial copy of the transgene.

FIG. 4

Expression of human globin mRNA in transgenic mice containing the BGT35 construct. S1 nuclease analysis on fetal liver RNA of 15.5 day F₀ transgenic mice showing BGT35 is expressed to significant levels in 5/7 transgenic mice. These data show that the β-globin promoter element and intron 2 sequence are not sufficient for reproducible single-copy transgene expression. Hγ, human Aγ-globin protected probe fragment; Mβ, mouse β major protected probe fragment; N, nontransgenic; C, 50-48, the highest expressing BGT50 single-copy transgenic mouse (discussed in text, see FIG. 6); 3X, probe excess control.

FIG. 5

Expression of human globin mRNA in transgenic mice containing the BGT54 construct. S1 nuclease analysis on fetal liver RNA of 15.5 day F₀ transgenic mice showing that BGT54 is expressed to significant levels in 13/15 transgenic mice. These data show that the β-globin promoter element and 3′ enhancer sequence are not sufficient for reproducible single-copy transgene expression. Hγ, human Aγ-globin protected probe fragment; Mβ, mouse β major protected probe fragment; N, nontransgenic; C, 50-48, the highest expressing BGT50 single-copy transgenic mouse (discussed in text, see FIG. 6); Copy #=1*, one intact copy plus a partial copy of the transgene.

FIG. 6

Expression of human globin mRNA in transgenic mice containing the BGT50 construct. S1 nuclease analysis on fetal liver RNA of 15.5 day F₀ transgenic mice showing that BGT50 is expressed in all 8 animals including 7 single-copy mice. These data show that the β-globin intron 2 and 3′ enhancer elements are sufficient for reproducible transgene expression when linked to the 5′HS3 element and the β-globin promoter. Hγ, human Aγ-globin protected probe fragment; Mβ, mouse β major protected probe fragment; N, nontransgenic; C, 50-48, the highest expressing BGT50 single-copy transgenic mouse; Copy #=1*, one intact copy plus a partial copy of the transgene.

FIG. 7

Expression of human globin mRNA in transgenic mice containing the BGT76 construct. S1 nuclease analysis on fetal liver RNA of 15.5 day F₀ transgenic mice showing that BGT76 is expressed in all 17 animals including 5 single-copy mice. These data show that activation of single-copy transgenes by a functional interaction between 5′HS3, the β-globin intron 2, and 3′ enhancer elements is not specific for the β-globin promoter. Hγ, human Aγ-globin protected probe fragment; Mβ, mouse β major protected probe fragment; N, nontransgenic; C, 50-48, the highest expressing BGT50 single-copy transgenic mouse (discussed in text, see FIG. 6); Copy #=1*, one intact copy plus a partial copy of the transgene.

FIG. 8

FIG. 8A shows the sequence of SEQ ID NO:1.

In a preferred embodiment, the figure shows DNA nucleotide sequence of the BGT50 construct including the human β/γ-globin hybrid nucleic acid molecule of the invention, and the 5′HS3 element.

FIG. 8B shows the sequence of SEQ ID NO:2.

In a preferred embodiment, the figure shows DNA nucleotide sequence of the BGT50 construct including a coding sequence, the human β/γ-globin hybrid nucleic acid molecule of the invention, and the 5′HS3 element.

FIG. 9

FIG. 9A shows the sequences of SEQ ID NO:3.

In a preferred embodiment, the figure shows DNA nucleotide sequence of the BGT76 construct including the human β/γ-globin hybrid nucleic acid molecule of the invention, and the 5′HS3 element,

FIG. 9B shows the sequences of SEQ ID NO:4.

In a preferred embodiment, the figure shows DNA nucleotide sequence of the BGT76 construct including a coding sequence, the human β/γ-globin hybrid nucleic acid molecule of the invention, and the 5′HS3 element.

FIG. 10

This figure shows a preferred embodiment of the hybrid nucleic acid molecule of the invention, as well as variations.

Maps of BGT50 and BGT76 constructs defining critical regulatory elements. According to the BGT50 sequence, the coordinates of these regulatory elements are as follows: A about 850 bp 5′HS3 (about 28-882 bp); B about 815 bp β-globin promoter and the 5′UTR (about 903-1771 bp); C β-globin intron 2 (2191-3108 bp); D β-globin 3′ enhancer (about 3655-3912 bp). BGT 76 contains A, C and D elements but not the β element which has been replaced with the Aγ-globin promoter (E element). According to the BGT 76 sequence, the coordinates of these regulatory elements are as follows: A (about 23-877 bp); E about 700 bp Aγ-globin promoter and 5′UTR (about 896-1655 bp); C (about 2075-2992 bp); D (about 3539-3796 bp).

DETAILED DESCRIPTION OF THE INVENTION

The invention satisfies the need for suitable hybrid nucleic acid molecules for erythroid and precursor cell gene therapy treatment of hemoglobinopathies. The hybrid nucleic acid molecules contain human β-globin DNA regulatory elements which naturally express therapeutic polypeptides, preferably, α-, β- δ-, ε-, γ-, or ζ-globin polypeptides or their derivatives having globin activity. The hybrid nucleic acid molecules direct a high level of nucleic acid molecule expression in vitro and in vivo. The hybrid nucleic acid molecules are safe and confer a sustained and appropriate level of cell-specific expression for gene therapy. The hybrid nucleic acid molecules may be used in cells of the erythroid lineage, such as erythroid cells or their precursors, bone marrow, umbilical cord blood cells, or cells sorted from them including hematopoietic stem cells that are CD34−/CD38−, or CD34+/CD38−, progenitor cells of the erythroid lineage such as CFU-GEMM, BFU-E and CFU-E, or erythroid cells such as pro-erythroblasts, erythroblasts, or erythrocytes. The cells are preferably mammalian cells (eg. murine cells) and more preferably human cells. Globin genes are known in the art. The sequences described in this application (including regulatory elements) as well as globin derivatives may be readily obtained from a number of sources, such as Genbank (National Center for Biotechnology Information, USA or the Globin Gene Server Databases (Laboratories of Computer Science & Engineering and Biochemistry & Molecular Biology at the Pennsylvania State University, USA.

In a preferred embodiment, the hybrid nucleic acid molecules may be as shown in FIG. 10. This figure provides maps of the preferred BGT50 and BGT76 constructs showing the regulatory elements. A generic sequence is as follows: 5′-A-X-C-D-3′, wherein A includes a 5′HS3, X includes a B-globin promoter or an Aγ-globin promoter, C includes a β-globin intron 2 and D includes a β-globin 3′ enhancer. These sequences may be modified. Additional regulatory elements may also be used and these will be apparent to a person skilled in the art.

More preferably the generic sequence is 5′-A-X-Y-C-D-3′ wherein A is a 5′HS3, X includes a β-globin promoter or an Aγ-globin promoter, Y includes a coding nucleic acid molecule of interest (preferably a γ-globin sequence, another globin gene or a derivative thereof), C includes a β-globin intron 2 and D includes a β-globin 3′ enhancer. These sequences may be modified. Additional regulatory elements may also be used and these will be apparent to a person skilled in the art.

The invention includes a method for delivering a gene encoding a globin polypeptide to the cells of an individual with a hemoglobinopathy, comprising administering to the individual a vector comprising a hybrid nucleic acid molecule including a coding nucleic acid molecule encoding a globin polypeptide or a derivative thereof.

The invention also includes a method for providing an individual having a hemoglobinopathy with biologically active globin protein, comprising administering to the individual a vector comprising a hybrid nucleic acid molecule including a coding nucleic acid molecule encoding a globin polypeptide or a derivative thereof.

The invention also includes a method for producing a stock of recombinant virus comprising a hybrid nucleic acid molecule including a coding nucleic acid molecule encoding a globin polypeptide or a derivative thereof.

Hybrid Nucleic Acid Molecules

The invention relates to hybrid nucleic acid molecules for expressing coding nucleic acid molecules (the term “coding nucleic acid molecule” includes the term “transgene”) that produce globin polypeptides in cells of the erythroid lineage. The globin polypeptides are preferably, α-, β- α-, ε-, γ-, or ζ-globin polypeptides or their derivatives having globin activity such that the globin is capable of forming part of a hemoglobin complex for transporting oxygen. Examples of globin derivatives are described in U.S. Pat. No. 5,861,488 (LeBoulch and London, issued to MIT) which is incorporated by reference in its entirety. The hybrid nucleic acid molecules are also useful for expressing other nucleic acid molecules of interest. The hybrid nucleic acid molecules are preferably constructed from human β-globin DNA regulatory elements that naturally express nucleic acid molecules in cells of the erythroid lineage. The regulatory element sequences may be modified according to known techniques while retaining the desired activities. These , β-globin DNA regulatory elements are used to direct the expression of coding nucleic acid molecules for use in research, protein production and gene therapy in cells of the erythroid lineage. Since the hybrid nucleic acid molecules use mammalian (murine or more preferably human) DNA regulatory elements that are specifically expressed in cells of the erythroid lineage, high levels of protein expression are produced.

Other preferred coding nucleic acid molecules include 1) a nucleic acid molecule having at least about 70% sequence identity to a β-globin nucleic acid molecule, a γ-globin nucleic acid molecule, a δ-globin nucleic acid molecule, a ε-globin nucleic acid molecule, a ζ-globin nucleic acid molecule and an α-globin nucleic acid molecule and encoding a protein having β-globin, γ-globin, δ-globin, ε-globin, ζ-globin or α-globin activity, respectively, and 2) a nucleic acid molecule encoding a protein having β-globin, γ-globin, ε-globin, ζ-globin, ζ-globin, or α-globin activity, such that the globin is capable of forming part of a hemoglobin complex for transporting oxygen. Changes in the nucleotide sequence which result in production of a chemically equivalent (for example, as a result of redundancy of the genetic code) or chemically similar amino acid (for example where sequence similarity is present), may also be made to produce therapeutic polypeptides using the hybrid nucleic acid molecules of the invention.

The hybrid nucleic acid molecules may be used in vivo or in vitro. Cells transfected or transduced in vitro can be used for ex vivo gene therapy or as a research tool or for protein production. The hybrid nucleic acid molecules are also useful for gene therapy by transfecting or transducing cells in vivo to express a therapeutic protein. Gene therapy may be used to treat diseases, disorders or abnormal physical states of cells of the erythroid lineage, such as hemoglobinopathies. For example, if one were to upregulate the expression of a gene, one could insert the sense sequence into the hybrid nucleic acid molecule. If one were to downregulate the expression of the gene, one could insert the antisense sequence into the expression cassette. Techniques for inserting sense and antisense sequences (or fragments of these sequences) would be apparent to those skilled in the art. The nucleic acid molecule or nucleic acid molecule fragment may be either isolated from a native source (in sense or antisense orientations) or synthesized. It may also be a mutated native or synthetic sequence or a combination of these.

Variations of Hybrid Nucleic Acid Molecules

Modifications

Many modifications may be made to the hybrid nucleic acid molecule DNA sequences disclosed in this application and these will be apparent to one skilled in the art. The invention includes nucleotide modifications of the sequences disclosed in this application (or fragments thereof) that are capable of directing single copy expression in cells of the erythroid lineage. For example, a β-globin regulatory sequences may be modified or a nucleic acid sequence to be expressed may be modified using techniques known in the art. Modifications include substitution, insertion or deletion of nucleotides or altering the relative positions or order of nucleotides.

Sequence Identity

The hybrid nucleic acid molecules of the invention also include nucleic acid molecules (or a fragment thereof) having at least about: 70% identity, at least 80% identity, at least 90% identity, at least 95% identity, at least 96% identity, at least 97% identity, at least 98% identity or, most preferred, at least 99% or 99.5% identity to a hybrid nucleic acid molecule of the invention and which are capable of single copy expression of nucleic acid molecules in cells of the erythroid lineage. Identity refers to the similarity of two nucleotide sequences that are aligned so that the highest order match is obtained. Identity is calculated according to methods known in the art. For example, if a nucleotide sequence (called “Sequence A”) has 90% identity to a portion of SEQ ID NO: 1, then Sequence A will be identical to the referenced portion of SEQ ID NO: 1 except that Sequence A may include up to 10 point mutations (such as substitutions with other nucleotides) per each 100 nucleotides of the referenced portion of SEQ ID NO: 1.

Sequence identity for BGT50 and BGT76 (each construct preferably without a coding nucleic acid molecule insert) is preferably set at at least about: 70% identity, at least 80% identity, at least 90% identity, at least 95% identity, at least 96% identity, at least 97% identity, at least 98% identity or, most preferred, at least 99% or 99.5% identity to the sequences of BGT50 or BGT76 provided (such as SEQ ID NO:1-SEQ ID NO:4 or its complementary sequence) or the 5′HS3 promoter, intron 2 and 3′ enhancer regions or other regions described in this application, taken in combination or separately). Sequence identity will preferably be calculated with the GCG program from Bioinformatics (University of Wisconsin). Other programs are also available to calculate sequence identity, such as the Clustal W program (preferably using default parameters; Thompson, JD et al., Nucleic Acid Res. 22:4673-4680).

Hybridisation

The invention includes DNA which has a sequence with sufficient identity to a hybrid nucleic acid molecule described in this application to hybridize under stringent hybridization conditions (hybridization techniques are well known in the art). The present invention also includes nucleic acid molecules that hybridize to one or more of the sequences in SEQ ID NO:1-SEQ ID NO:4 or its complementary sequence. Such nucleic acid molecules preferably hybridize under high stringency conditions (see Sambrook et al. Molecular Cloning: A Laboratory Manual, Most Recent Edition, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.), High stringency washes have preferably have low salt (preferably about 0.2% SSC) and a temperature of about 50-65 (C.

Regulatory Elements

One skilled in the art would also appreciate that as other regulatory elements in β-globin or nucleic acid molecules to be expressed are identified, these may be used with the hybrid nucleic acid molecules of the invention. Regulatory elements from the β-globin gene in mammals other than humans could be inserted in the hybrid nucleic acid molecule provided that adequate single copy nucleic acid molecule expression still occurs. Regulatory elements from other nucleic acid molecules that are similar to those from the β-globin gene may also be used in the hybrid nucleic acid molecules. These regulatory elements may easily be inserted in hybrid nucleic acid molecules of the invention and the levels of expression measured. For example, regulatory sequences from β-globin genes from other mammals having a high level of sequence identity to the human regulatory elements used in the expression cassettes of the invention may be easily identified by reviewing sequences as they become available in a database, such as Genbank. Suitable sequences preferably have at least about: 70% identity, at least 80% identity, at least 90% identity, at least 95% identity, at least 96% identity, at least 97% identity, at least 98% identity or most preferably have at least 99% or 99.5% identity to the sequence of a regulatory element used in the hybrid nucleic acid molecules of the invention disclosed in this application (or a fragment thereof).

Host Cells

The invention also relates to a host cell (isolated cell in vitro, a cell in vivo, or a cell treated ex vivo and returned to an in vivo site) containing a hybrid nucleic acid molecule of the invention. Cells transfected with a hybrid nucleic acid molecule as a DNA molecule, or transduced with the hybrid nucleic acid molecule as a DNA or RNA virus vector, may be used, or example, in bone marrow or cord blood cell transplants according to techniques known in the art. Examples of the use of transduced bone marrow or cord blood cells in transplants are for ex vivo gene therapy of Adenosine deaminase (ADA) deficiency. Other cells which may be transfected or transduced either ex vivo or in vivo include purified hematopoietic stem cells that are CD34−/CD38−, or CD34+/CD38− in surface marker phenotype, or progenitor cells of the erythroid lineage such as CFU-GEMM, BFU-E and CFU-E, or erythroid cells such as pro-erythroblasts, erythroblasts, or erythrocytes.

Since the DNA regulatory elements used in the hybrid nucleic acid molecules are from human genome, these elements are highly compatible for human gene therapy because the authentic protein factors interacting with these DNA elements are present in targeted cells. These hybrid nucleic acid molecules are erythroid cell-specific and highly efficient. The cell-specificity increases the efficacy and avoids any adverse effects resulting from expression of the therapeutic nucleic acid molecule in non-targeted cells. The high efficiency of gene expression is also critical to minimize the dosage of the therapeutic reagents from gene therapy. Thus, sufficient amounts of the hybrid nucleic acid molecules may be delivered and expressed to confer the phenotype of the expressed polypeptide to the cells (for example, globin activity in erythroid cells).

Pharmaceutical Compositions

The pharmaceutical compositions of this invention used to treat patients having diseases, disorders or abnormal physical states of the cells described in this application could include an acceptable carrier, auxiliary or excipient.

The pharmaceutical compositions can be administered by ex vivo and in vivo methods such as electroporation, DNA microinjection, liposome DNA delivery, and virus vectors that have RNA or DNA genomes including retrovirus vectors, lentivirus vectors, Adenovirus vectors and Adeno-associated virus (AAV) vectors, Semliki Forest Virus. Derivatives or hybrids of these vectors may also be used.

Dosages to be administered depend on patient needs, on the desired effect and on the chosen route of administration. The expression cassettes may be introduced into the cells or their precursors using ex vivo or in vivo delivery vehicles such as liposomes or DNA or RNA virus vectors. They may also be introduced into these cells using physical techniques such as microinjection or chemical methods such as coprecipitation. The nucleic acid molecules may be introduced into cells of the erythroid lineage, such as erythroid cells or their precursors, such as bone marrow or cord blood cells, purified hematopoietic stem cells that are CD34−/CD38−, or CD34+/CD38−, or progenitor cells of the erythroid lineage such as CFU-GEMM, BFU-E and CFU-E, or erythroid cells such as pro-erythroblasts, erythroblasts, or erythrocytes using these techniques.

The pharmaceutical compositions can be prepared by known methods for the preparation of pharmaceutically acceptable compositions which can be administered to patients, and such that an effective quantity of the hybrid nucleic acid molecule is combined in a mixture with a pharmaceutically acceptable vehicle. Suitable vehicles are described, for example in Remington's Pharmaceutical Sciences (Remington's Pharmaceutical Sciences, Mack Publishing Company, Easton, Pa., USA).

On this basis, the pharmaceutical compositions could include an active compound or substance, such as a hybrid nucleic acid molecule, in association with one or more pharmaceutically acceptable vehicles or diluents, and contained in buffered solutions with a suitable pH and isoosmotic with the physiological fluids. The methods of combining the expression cassettes with the vehicles or combining them with diluents is well known to those skilled in the art. The composition could include a targeting agent for the transport of the active compound to specified sites within the erythroid or other cells.

Method of Medical Treatment of Disease

Vectors containing the nucleic acid molecules of the invention may be administered to mammals, preferably humans, in gene therapy using techniques described below. The polypeptides produced from the hybrid nucleic acid molecules may also be administered to mammals, preferably humans.

Gene Therapy

Gene therapy to replace globin expression is useful to modify the development or progression of hemoglobinopathies such as sickle cell anemia and thalassemia. The invention includes compositions and methods for providing a nucleic acid molecule encoding globin to a subject such that expression of the molecule in the cells provides the biological activity of globin and/or phenotype of globin to those cells. The invention also includes compositions and methods for providing gene therapy for treatment of diseases, disorders or abnormal physical states characterized by insufficient globin expression or inadequate levels or activity of globin polypeptide. The compositions and methods specifically deliver high levels of hybrid nucleic acid molecule and high levels of expression in order to provide biological activity of globin and/or pheonotype of globin to cells. One would want at least about 20 and preferably at least about 50% of normal normal wild-type endogenous beta or alpha globin RNA and/or polypeptide levels. HS1, HS2, HS4 and insulator elements, or a combination thereof may be added to the vector to improve the levels of gene expression.

The invention includes methods and compositions for providing a coding nucleotide sequence encoding globin or biologically functional equivalent nucleotide sequence to the cells of an individual such that expression of globin in the cells provides the biological activity or phenotype of globin polypeptide to those cells. Sufficient amounts of the nucleotide sequence are administered and expressed at sufficient levels to provide the biological activity or phenotype of globin polypeptide to the cells. For example, the method can involve a method of delivering and expressing a nucleic acid molecule encoding globin to the cells of an individual having a disease, disorder or abnormal physical state, comprising administering to the individual a vector comprising a hybrid nucleic acid molecule of the invention including a coding nucleic acid molecule encoding globin that can at single copy produces globin. The method also relates to a method for providing an individual having a disease, disorder or abnormal physical state with biologically active globin polypeptide by administering a nucleic acid molecule encoding globin. The method may be performed ex vivo or in vivo. Gene therapy methods and compositions are demonstrated, for example, in U.S. Pat. Nos. 5,869,040, 5,639,642, 5,928,214, 5,911,983, 5,830,880, 5,910,488, 5,854,019, 5,672,344, 5,645,829, 5,741,486, 5,656,465, 5,547,932, 5,529,774, 5,436,146, 5,399,346 and 5,670,488, 5,240,846. The amount of polypeptide will vary with the subject's needs. The optimal dosage of vector may be readily determined using emperical techniques, for example by escalating doses (see U.S. Pat. No. 5,910,488 for an example of escalating doses). As mentioned above, at least about 20 and preferably at least about 50% of normal wild type endogenous beta or alpha globin RNA and/or polypeptide levels is provided to the subject. Other polypeptides may also be delivered using the hybrid nucleic acid molecules of the invention.

Various approaches to gene therapy may be used. The invention includes a process for providing a human with a therapeutic polypeptide including: introducing human cells into a human, said human cells having been treated in vitro or ex vivo to insert therein a vector of the invention at single copy which encodes a globin polypeptide, the human cells expressing in vivo in said human a therapeutically effective amount of said therapeutic polypeptide.

In another embodiment, the invention includes a method for providing biologically active globin polypeptide to the cells of an individual with a hemoglobinopathy, including: introducing an enriched bone marrow hematopoietic progenitor cell population having been treated in vitro or ex vivo to insert therein a DNA molecule at single copy encoding globin polypeptide, the progenitor cell population expressing in said individual biologically active globin polypeptide. In another embodiment, the method of gene therapy includes a method for providing biologically active globin polypeptide to the cells of an individual with a hemoglobinopathy, including:

(a) isolating autologous bone marrow from the individual with the hemoglobinopathy;

(b) enriching the autologous bone marrow for hemapoietic progenitor cells to obtain an enriched hemapoietic progenitor cell population;

(c) transducing the enriched progenitor cell population with the vector of the invention wherein the vector is capable of expressing the globin polypeptide; and

(d) transplanting the transduced autologous progenitor cell population into the individual with the hemoglobinopathy so as to provide to the individual biologically active globin polypeptide.

The above methods may be used for medical treatment of any diseases, disorders or abnormal physical states in a cell of an erythroid lineage, preferably including hemoglobinopathy, sickle cell anemia, β-thalassemia and α-thalassemia. The globin is preferably one of the globin genes discussed above, or a derivative.

The method also relates to a method for producing a stock of recombinant virus by producing virus suitable for gene therapy comprising modified DNA encoding globin. This method preferably involves transfecting cells permissive for virus replication (the virus containing modified globin) and collecting the virus produced.

Typically, a male or female is treated with the vector containing the invention (subject age can vary, but subjects include children or adults). An anemic patient patient suffers from tissue hypoxia and anemia symptoms result from cardiovascular and pulmonary responses to the hypoxia. At the time of treatment, for example, a sickle cell anemia patient may have urinary isosthenuria, painful vaso-occlusive crises and leg ulcers. Electrophoesis will show S hemoglobin. A thalassemia patient may have splenomegaly and bony changes on x-ray. A2 and F hemoglobin are often elevated in these patients. The vector containing the invention is preferably administered ex vivo in order to achieve a desired level of polypeptide in the patient. Treatments are repeated as deemed appropriate by a physician to ameliorate the clinical symptoms of disease. Such treatments may be life-long or temporary. Patients report significant reduction in the symptoms described above.

Other hemoglobinopathy, anemias or erythroid diseases, disorders or abnormal physical states that require erythroid specific expression may also be treated. The hybrid nucleic acid molecules are useful for expressing any genes in cells of the erythroid lineage in mammals (including mice or humans), such as genes encoding G6PD or ferrochelatase RNA and/or polypeptides. Marker genes may also be used, such as green fluorescent protein. Derivatives of these polypeptides or globin polypeptides may also be used.

Cotransfection (DNA and marker on separate molecules) may be employed (see eg U.S. Pat. No. 5,928,914 and U.S. Pat. No. 5,817,492). As well, a marker (such as Green Fluorescent Protein marker or a derivative) may be used within the vector itself (preferably a viral vector).

Polypeptide Production and Research Tools

Mammals and cell cultures transfected, transformed or transduced with the hybrid nucleic acid molecules of the invention are useful as research tools. BGT50 and BGT76 are useful as research tools as are other hybrid nucleic acid molecules. Mammals and cell cultures are used in research according to numerous techniques known in the art. For example, one may obtain mice that do not express an α-globin protein and use them in experiments to assess expression of a recombinant α-globin nucleotide sequence under the control of β-globin regulatory elements. In an example of such a procedure, experimental groups of mice are transfected or transduced with vectors containing recombinant α-globin genes (or variants of α-globin or fragments of α-globin) under the control of β-globin regulatory elements to assess the levels of protein produced, its functionality and the phenotype of the mice (for example, physical characteristics of the erythroid cell structure). Some of the changes described above to optimize expression may be omitted if a low level of expression is desired. It would be obvious to one skilled in the art that changes could be made to alter the levels of protein expression.

In another example, a cell line (either an immortalized cell culture or a stem cell culture) is transfected or transduced with a hybrid nucleic acid molecule of the invention (or variants) to measure levels of expression of the nucleic acid molecule and the activity of the nucleic acid molecule. For example, one may obtain mouse or human cell lines or cultures bearing the hybrid nucleic acid molecule of the invention and obtain expression after the transfer of the cells into immunocompromised mice such as NOD/SCID mice.

The hybrid nucleic acid molecules may be used in research to deliver marker genes or antisense RNA to cells.

The invention includes a method for producing a recombinant host cell capable of expressing a nucleic acid molecule of the invention comprising introducing into the host cell a vector of the invention.

The invention also includes a method for expressing a polypeptide in a host cell of the invention including culturing the host cell under conditions suitable for coding nucleic acid molecule expression. The method preferably provides the phenotype of the polypeptide (such as a globin polypeptide or derivative) the cell.

In these methods, the host cell is preferably a cell of the erythroid lineage selected from the group consisting of: an erythroid cell, an erythroid cell precursor, a bone marrow cell, an umbilical cord blood cell, a hematopoietic stem cell that is CD34−/CD38−, or CD34+/CD38−, a progenitor cell of the erythroid lineage, CFU-GEMM, BFU-E, CFU-E, a pro-erythroblast, an erythroblast and an erythrocyte.

Another aspect of the invention is an isolated polypeptide produced from a nucleic acid molecule or vector of the invention according to a method of the invention.

Using Exogenous Agents in Combination with the Hybrid Nucleic Acid Molecule

Cells transfected or transduced with a hybrid nucleic acid molecule may, in appropriate circumstances, be treated with conventional medical treatment of hemoglobinopathies, such as blood transfusions and iron chelators. The appropriate combination of treatments would be apparent to a skilled physician.

IDENTIFICATION OF β-GLOBIN REGULATORY ELEMENTS

Chromatin Opening by the β-globin LCR 5′HS3 Element

The human β-globin LCR is composed of four developmentally stable and erythroid-specific DNaseI hypersensitive sites termed 5′HS 1-4 [2, 11, 12]. The LCR causes high level expression of the β-globin gene locus in cells of the erythroid lineage and each HS seems to provide a unique function for global LCR activation. The LCR activity of each individual HS has been studied extensively in cell culture systems and transgenic mice. Chromatin opening mediated by the human β-globin LCR does not require all four of the HS elements. We have used single-copy transgenic mouse lines to map the LCR chromatin opening activity to a 1.9 kb 5′HS3 fragment when it is linked to the reporter β-globin gene, but expression levels are reduced to about 25% [13]. A transgene construct that contains a dominant chromatin opening activity will escape negative position effects resulting from the neighboring chromatin structure and will express significantly at all single-copy transgene integration sites. In contrast, reproducible expression is not obtained from single-copy transgenes regulated by the 5′HS2 element [14]. DNaseI digestion experiments demonstrated that 5′HS3, but not 5′HS2, could open chromatin at all integration sites tested [13]. In other words, the single-copy transgene assay distinguished between the 5′HS2 classical enhancer element and the 5′HS3 chromatin-opening activity.

Our additional studies used transient day 15.5 embryonic “founder” mice and demonstrated that the minimal 125 bp 5′HS3 core element is not sufficient for single-copy β-globin transgene expression in fetal liver RNA [15]. We also identified an 850 bp 5′HS3 fragment that directs single-copy β-globin transgene expression when part of a larger 3.0 kb LCR [15]. We showed that this 850 bp 5′HS3 element alone confers reproducible single-copy transgene expression on a linked β-globin gene (BGT9 construct, FIG. 1) in transient transgenic mice. However, 5′HS3 is incapable of similarly activating a linked Aγ-globin transgene (BGT26, FIG. 1). These findings show that single-copy transgene expression by 5′HS3 requires cooperation with additional sequences present in the β-globin gene.

Regulatory Elements in the β-globin Gene

Various regulatory elements within the individual β-globin-like genes have been reported and these regulatory elements are responsible for the stage-specific and tissue-specific expression characteristics of the β-globin locus. The β-globin gene in particular has been reported to contain two tissue-specific enhancers, one being an intragenic enhancer in intron 2 (βivs2) [16] and one being 3′ to the gene [17]. Furthermore, βivs2 contains a matrix attachment region (MAR) that may influence β-globin gene expression in its natural context. We identified β-globin regulatory elements present within BGT9 that functionally interact with 5′HS3 include the 815 bp promoter, the enhancer or nearby MAR located in βivs2, or the 3′ enhancer.

The minimal β-globin promoter maps to a 103 bp fragment that is inducible by the LCR in stable transfection studies and which has been fully footprinted for transcription factor binding sites [18]. LCR activation of multicopy γ-globin transgenes has also been demonstrated to be dependent on the length of the γ-globin promoter [19]. However, the importance of globin promoters in LCR activation has not been systematically evaluated in single-copy transgenic mice. We previously noted that the 265 bp β-globin promoter commonly used in gene therapy vectors does not direct reproducible expression in single-copy transgenic mice regulated by the 3.0 kb LCR cassette [15]. In contrast, the same LCR cassette directed single-copy expression from the 815 bp β-promoter. These findings show that the β-globin promoter has a role in LCR activation.

β-globin enhancers have no role in LCR-mediated induction of the promoter in stable transfection studies [18, 21] and were therefore omitted from β-globin gene therapy vectors [10, 22, 23]. However, deletion of the β-globin 3′ enhancer in YAC transgenic mice causes a reduction in β-globin gene expression indicating that the β-globin 3′ enhancer influences globin switching [9]. In addition, the human LCR does not reproducibly activate multicopy γ-globin transgene promoters unless a fragment containing the 3′ Aγ-globin enhancer [5] or the entire β-globin gene is included [6, 7]. Hence, more recently developed AAV vectors that transfer the Aγ-globin gene include the 3′ enhancer [24]. Most recently, it was shown that deletion of the Aγ-globin 3′ enhancer in YAC transgenic mice had no effect on transgene expression, throwing some confusion into interpreting these conflicting data. We have shown that reproducible expression from single-copy β-globin transgenes regulated by a 4.0 kb LCR cassette requires a 3′ element which includes the β-globin 3′ enhancer [8].

β-globin Regulatory Elements Required for Single-copy Transgene Activation by 5′HS3

We fused various β-globin regulatory elements to Aγ-globin coding sequences, and linked these hybrid transgene cassettes to the 850 bp 5′HS3 element. We employed these constructs to fine map the β-globin sequences required for reproducible single-copy transgene expression activity. We showed that the β-globin intron 2 and 3′ enhancer are involved in single-copy transgene expression activity mediated by the human β-globin LCR. In addition, we have extended the utility of the β-globin LCR to include expression of the Aγ-globin gene. Such a β/γ-globin hybrid gene is ideally suited for gene therapy of sickle cell anemia because γ-globin protein has better anti-sickling properties than β-globin.

Identifying the Minimal Regulatory Elements to Express a Hybrid Nucleic acid Molecule

Definition of the minimal combination of regulatory elements capable of directing expression of the human β-globin gene in single-copy transgenic mice serves the dual purpose of: 1) examining the functional and cooperative interactions of these elements; as well as 2) creating a transgene cassette whose expression levels are well suited for gene therapy purposes. In this study, we define the minimal combination of β-globin gene sequences capable of directing reproducible single-copy transgene expression when linked to 5′HS3. Transgenic mice were used because they provide the most reliable approach to the analysis of mammalian gene expression at the whole organism level. The transgenic mouse model shows that the hybrid nucleic acid molecule functions in other mammals, such as humans.

Our results demonstrate that single-copy expression directed by 5′HS3 is only obtained in the presence of both β-globin intron 2 and 3′ enhancer elements. The BGT50 hybrid globin transgene is ideal for gene therapy of hemoglobinopathies because it expresses reproducibly at single-copy and expresses the Aγ-globin gene under β-globin gene regulation. γ-globin protein has better antisickling properties than β-globin [29], and low level expression of γ-globin is known to ameliorate the symptoms of both sickle cell anemia and β-thalassemia.

Requirement for β-globin Intron 2 and 3′ Enhancer Elements

The BGT9 construct demonstrates that 850 bp 5′HS3 fragment directs approximately 70% levels of β-globin gene expression at single copy, and confirms that 5′HS3 linked to the β-globin gene is reproducibly expressed at single-copy. The results from the BGT26 transgenic mice establish that the 5′HS3 element cannot reproducibly express the Aγ-globin gene and requires the presence of β-globin gene sequences for activation of single-copy transgenes. A series of β/γ-globin hybrid genes were constructed to define the minimal combination of β-globin gene sequences required for single-copy transgene expression. We conclude from the BGT34 construct that the β-globin promoter is not sufficient for this activity, from the BGT35 construct that the β-globin promoter and β-globin intron 2 are not sufficient, and from the BGT54 construct that the β-globin promoter and β-globin 3′ enhancer are not sufficient. In contrast, only the simultaneous presence of the β-globin intron 2 and 3′ enhancer in the BGT9, BGT50, and BGT76 constructs was sufficient to confer reproducible single-copy transgene expression directed by 5′HS3. The β-globin promoter is not essential as it can be replaced by the Aγ promoter in the BGT76 construct with little effect on single copy transgene expression. BGT76 includes the Aγ-promoter. HPFH mutations may be made to permit the BGT76 hybrid nucleic acid molecule to be better expressed in adult blood cells. These results show that a functional interaction between 5′HS3, the β-globin intron 2, and 3′ enhancer elements is absolutely required for single-copy transgene activation.

Relevance to Gene Therapy of the Hemoglobinopathies

The ability of our hybrid genes to express to high levels at all integration sites and at single copy can be applied to both erythroid-specific transgene expression cassettes in mice and for gene therapy. For example, BGT50 is the first description of Aγ-globin coding sequences controlled by the β-globin regulatory elements, and is well suited for DNA- or viral-mediated gene therapy of both sickle cell anemia and β-thalassemia. Given that BGT50 hybrid transgenes express reproducibly in the fetal livers of transgenic mice, we predict that they will also function when transferred directly into stem cells from cord blood or adult bone marrow, or purified hematopoietic stem cells during a gene therapy protocol. Its 3.9 kb size is small enough for insertion into AAV and retrovirus gene therapy vectors, as well as derivatives of retroviruses (hybrid vectors). The hybrid nucleic acid molecules may also be injected or transfected as a DNA plasmid. However, the MAR element in BGT50 has been reported to be deleterious to retrovirus replication [10, 23]. Viral mediated transfer of the hybrid nucleic acid molecules for gene therapy might be best accomplished with alternative vectors such as Semliki Forest Virus.

Finally, the BGT50 and BGT76 constructs extend the utility of the β-globin LCR in transgenic mice to include reproducible expression of Aγ-globin transgenes. Any nucleic acid molecule could be expressed to high levels in cells of the erythroid lineage by inserting its cDNA or genomic exon/intron sequences (from the ATG site to 3′ untranslated sequences) between the NcoI and BamHI sites of BGT50. In this manner, the β-globin intron 2 would function as part of a 3′ untranslated region, and the β-globin polyadenylation sites would be used for transcription termination. Such an expression cassette may be extremely useful for directing high level erythroid expression of non-globin transgenes in mice. A candidate nucleic acid molecule of therapeutic use would include the human γ-globin gene and the other genes described in this application.

EXPERIMENTS

In order to determine whether the 850 bp 5′HS3 element alone can direct reproducible single-copy transgene expression when linked to the β-globin gene, we created the BGT9 construct (FIG. 1). The β-globin gene sequences in BGT9 include the 815 bp β-globin promoter, the entire β-globin coding sequences including both introns, and 1.7 kb of 3′ sequences including the 3′ β-globin enhancer. To determine whether the 850 bp 5′HS3 element requires β-globin gene sequences for single copy transgene expression, we also linked the 850 bp 5′HS3 element to the Aγ-globin gene (BGT26 construct). BGT26 includes the 700 bp Aγ-globin promoter, the entire Aγ-globin coding sequences including both introns, and 2.0 kb of 3′ sequences including the 3′ Aγ-globin enhancer.

Experiment 1—Generation of Transgenic Mice

These DNA constructs were purified as linear fragments and microinjected into fertilized FVB mouse eggs in order to create transgenic mice. The fetuses derived from these eggs were dissected at embryonic day 15.5 and genomic DNA extracted from head tissue, while the fetal livers were frozen in two halves for future analyses. Positive transient transgenic founder (F₀) animals were identified by slot blot hybridization with the 51′HS3 probes, and transgene copy number subsequently deduced by genomic Southern blots after digestion with EcoR1 and BamH1, which we have previously shown can unambiguously identify junction fragments that define single-copy transgenic mice [15]. All founder animals were characterized to determine whether they harboured intact transgenes by Southern blot analysis with multiple diagnostic restriction enzymes and 5′HS3, βivs2, or Aγ-globin 3′ probes (data not shown). Finally, the proportion of transgenic cells in the fetal liver was compared to a bred line control by Southern blot analysis. DNA derived from one half of the frozen fetal livers was digested with Acc1 (BGT9) or Pst1 (Aγ-globin transgenes) and the transgene detected by the 5′HS3, βivs2, or βpromoter probes (data not shown). Animals containing a single non-intact transgene or highly mosaic animals (<10%) were excluded from this study.

Experiment 2—Requirement for β-globin Gene Sequences

To determine the effect of these transgene constructs on expression levels, RNA was extracted from frozen transgenic fetal livers for S1 nuclease protection assays. For the BGT9 construct, expression was analyzed using Hβ and Mβ probes (FIG. 2). As a standard sample for quantitation of Huβ RNA levels, we included fetal liver RNA from μD14 transgenic mice that express to approximately 100% levels. The BGT9 construct expresses significant levels of human β-globin mRNA in all 17 transgenic mice. Expression from three single-copy BGT9 mice ranges from 46-109% of the Mβ RNA, demonstrating that the 850 bp 5′HS3 element directs reproducible single-copy transgene expression when linked to the entire β-globin gene. In addition, the BGT9 construct appears to express to a higher level at single copy than the previously described 26% levels from the 1.9 kb 5′HS3 element [13].

Similar expression analysis was performed on the BGT26 transgene using the Hγ and Mβ probes (FIG. 3). As a standard RNA sample for all the Hγ S1 nuclease experiments, we included BGT50-48 RNA (labelled C in all figures). BGT50-48 is equivalent to the highest expressing single-copy BGT9 mouse, in that it contains one intact copy of the BGT50 construct (described later) and expresses γ-globin at 109% the level of Mβ (mean value from 8 experiments). Analysis of BGT26 transgenic mice shows very low levels of Aγ-globin mRNA in 2 mice and an undetectable level in the third animal. These data demonstrate that 5′HS3 cannot direct reproducible transgene expression on a linked Aγ-globin gene and suggests that 5′HS3 must functionally interact with β-globin gene sequences in order to reproducibly activate single-copy transgenes.

Experiment 3 - Design of Novel 5′HS3 β/γ-globin Hybrid Transgenes

To identify the β-globin gene sequences required to obtain reproducible single-copy transgene expression, we created several novel hybrid globin genes linked to the 5′HS3 element (FIG. 1). BGT34 contains 5′HS3 linked to the β-globin 815 bp promoter and the Aγ-globin coding sequences terminating 375 bp downstream of exon 3. This construct does not contain the Aγ-globin 3′ enhancer, and the Aγ-globin intron 2 has no known enhancer activity. Expression by this construct would indicate that the β-globin promoter is sufficient for single-copy transgene by 5′HS3.

BGT35 is essentially the same as BGT34 but with a replacement of the Aγ-globin intron 2 sequences with the βivs2. This adds the β-globin intron 2 enhancer and MAR to the BGT34 construct, but also alters three amino acids in the Aγ-globin coding sequences to their equivalents in the β-globin gene (K104R, T112K, I116H). These changes do not alter amino-acids known to be important for anti-sickling effects [29]. Expression by BGT35 would indicate that both the β-globin promoter and intron 2 are sufficient for single-copy transgene activation by 5′HS3.

BGT54 is essentially the same as BGT34 but with the addition of the 200 bp β-globin 3′ enhancer 375 bp downstream of the Aγ-globin coding sequences. Expression by BGT54 would indicate that both the β-globin promoter and β-globin 3′ enhancer are sufficient for single-copy transgene activation by 5′HS3. BGT50 is essentially the same as BGT35 but with the β-globin 3′ enhancer inserted 375 bp downstream of the Aγ-globin exon 3. This construct also contains the three amino acid alteration in the Aγ-globin coding sequences. Expression by BGT50 would indicate that the β-globin promoter, β-globin intron 2 and β-globin 3′ enhancer are sufficient for single-copy transgene activation by 5′HS3.

Experiment 4—Expression of 5′HS3 β/γ-globin Hybrid Transgenes

Expression from each of the 5′HS3 β/γ-globin constructs was assayed in transgenic mice by S1 nuclease protection analysis in the fetal liver of 15.5 day transient transgenic mice as above. Of 7 BGT34 transgenic mice that include the 815 bp β-globin promoter (FIG. 3), 5 animals contained a single-copy of the transgene and one animal (34-71) contained one intact copy and a partial transgene (indicated by the asterisk). Only 3/5 single-copy animals and one four copy animal (34-45) expressed detectable levels of human Aγ-globin mRNA on a per copy basis. This finding demonstrates that the β-globin promoter is not sufficient to rescue reproducible expression from single-copy transgenes that lack a 3′ enhancer element.

Other candidate β-globin sequences that may functionally interact with 5′HS3 include the enhancers in βivs2 and 3′ of the gene. Therefore, we analyzed 5′HS3 Aγ-globin transgenes containing the 815 bp β-globin promoter and either βivs2 (BGT 35; FIG. 1) or the 3′ enhancer (BGT 54; FIG. 1) or both (BGT 50; FIG. 1). 3 out of 7 BGT35 animals contained one single intact transgene (FIG. 4). Of these single-copy mice, low or undetectable Aγ-globin mRNA levels were observed in 2 animals. These data show that the β-globin promoter and β-globin intron 2 are also not sufficient for reproducible transgene expression directed by 5′HS3. We generated six single-copy BGT54 animals (FIG. 5), two of which contained one intact transgene and a partial transgene (indicated by the asterisk). The “line” sample represents a single-copy bred line where RNA expression was assayed in the adult blood. BGT54 expresses significant levels of Aγ-globin mRNA in 5/6 single-copy animals including the adult blood sample of the BGT54 transgenic line. However, one single-copy and a three copy animal express undetectable levels of Aγ-globin mRNA. This finding demonstrates that the β-globin promoter and β-globin 3′ enhancer are not sufficient for reproducible transgene expression.

Finally, the BGT50 construct was tested in single-copy transgenic mice and significant expression was detected in all eight transgenic mice (FIG. 6). Seven single-copy animals were generated, two of which contained a partial transgene along with an intact transgene (indicated by the asterisk). One animal (50-225) is a single-copy bred line sample where RNA was assayed in the fetal liver. The average expression of single-copy transgenes is 71 % of Mβ levels and ranges from 40%-109%. Since only BGT50 was expressed in all single-copy kansgenic mice and, therefore, irrespective of the integration site, we conclude that reproducible single-copy transgene activation by 5′HS3 on the β-globin promoter requires a functional interaction with both βivs2 and the 3′ enhancer.

Experiment 5—Requirement for the β-globin Promoter

In order to determine whether the β-globin promoter is required, or that βivs2 and β-globin 3′ enhancer are themselves sufficient for single-copy transgene activation by 5′HS3, we created the BGT76 construct (FIG. 1). BGT76 is essentially the same as BGT50 with the replacement of the 815 bp β-globin promoter for the 700 bp Aγ-globin promoter. Expression by BGT76 would indicate that the functional interaction between 5′HS3 and these β-globin elements is not specific for activation of the β-globin promoter.

Expression from BGT76 was assayed in transgenic mice by S1 nuclease protection analysis in the fetal liver of 15.5 day transient transgenic mice as above. 17 of 17 BGT76 transgenic mice expressed detectable levels of human Aγ-globin mRNA (FIG. 7). Five single-copy animals were generated, three of which also contained a partial transgene (indicated by the asterisk). These single-copy transgenic mice expressed a mean 46% Mβ levels ranging from 12%-72%. This finding demonstrates that the activation of single-copy transgenes is not dependent on the presence of the β-globin promoter. We conclude that the Aγ-globin promoter can also be activated by a functional interaction between 5′HS3, β-globin intron 2 and 3′ elements.

MATERIALS AND METHODS

Plasmid Construction

Transgene constructs were derived from the plasmids pGSE1758 [28], pBGT14 [15], p141 [23], and pAγ-globin (provided by S. Philipsen). pGSE1758 contains a polylinker 5′ of the 4.2 kb Hβa1-EcoRV β-globin gene fragment regulated by the 815 bp promoter. pBGT14 contains a 3.0 kb LCR cassette and the 4.2 kb Hβa1-EcoRV β-globin gene fragment regulated by the 815 bp promoter [15]. The 3.0 kb LCR contains the 1.15 kb Stu1-Spe1 fragment of 5′HS4, the 0.85 kb Sac1-PvuII fragment of 5′HS3, and the 0.95 kb Sma1-Stu1 fragment of 5′HS2. p141 contains a SnaBI-PstI β-globin gene fragment which includes a 372 bp RsaI-RsaI deletion in intron 2.

BGT9 was constructed by inserting the 850 bp Sac1-PvuII fragment of 5′HS3 into the XhoI site of pGSE1758 using XhoI linkers. The 5.0 kb transgene including the entire β-globin gene was purified as an EcoRV fragment.

BGT26 replaces all the β-globin gene sequences in BGT9 between the Sal1-XbaI sites with the 4.3 kb BspHI fragment of Aγ-globin by blunt end ligation. This includes the Aγ-globin 700 bp promoter and 3′ enhancer. The 5.2 kb transgene was purified as an EcoRV fragment.

BGT34 inserts the 1.9 kb NcoI-HindIII fragment from Aγ-globin into the NcoI-EcoRV sites of BGT9 using an NheI linker at the incompatible HindIII and EcoRI overhangs. The Aγ-globin sequences extend from the ATG translation start site located at the NcoI site used for subcloning, to 375 bp 3′ of exon 3 including the polyA site but not the Aγ-globin 3′ enhancer. The end result is that BGT34 contains the 815 bp β-globin promoter controlling the entire Aγ-globin coding sequences and both introns. The 3.7 kb transgene was purified as an EcoRV-NheI fragment.

BGT35 inserts the β-globin intron 2 sequences as a BamHI-EcoRI fragment into the compatible BamHI-EcoRI sites of BGT34. These changes also replace 4 Aγ-globin codons (101-104) with β-globin exon 2 sequences, and 16 Aγ-globin codons (105-119) with β-globin exon 3 sequences. Of these 20 β-globin codons, 17 encode the same amino-acid as Aγ-globin. The three altered codons are described in the text. The end result is that BGT35 contains the 815 bp β-globin promoter and the β-globin intron 2 sequences controlling the Aγ-globin coding sequences. The 3.7 kb transgene was purified as an EcoRV-NheI fragment.

BGT50 contains a polylinker at the NheI site of BGT35 that adds EcoRV, AgeI, and ClaI sites 3′ of the hybrid globin gene. The 260 bp PstI fragment containing the β-globin 3′ enhancer was cloned into the NheI site using linkers. The end result is that BGT50 contains the 815 bp β-globin promoter, the βivs2, and the β-globin 3′ enhancer controlling the Aγ-globin coding sequences. The 3.9 kb transgene was purified as a ClaI fragment.

BGT54 contains the 3.0 kb ClaI-EcoRI fragment of BGT34 linked to the 850 bp EcoRI-ClaI fragment of BGT50. The end result is that BGT54 contains the 815 bp β-globin promoter and the β-globin 3′ enhancer controlling the entire Aγ-globin coding sequences and both introns. The 3.9 kb transgene was purified as a ClaI fragment.

BGT76 contains the 2.1 kb ClaI-BamHI fragment of BGT26 linked to the 1.7 kb BamHI-ClaI fragment of BGT50. The end result is that BGT76 contains the 700 bp Aγ-globin promoter, the βivs2, and β-globin 3′ enhancer controlling the Aγ-globin coding sequences. The 3.8 kb transgene was purified as a ClaI fragment.

Generation of Transgenic Mice

Transgene DNA was prepared using Plasmid Maxi Kits (Qiagen). Transgene fragments were liberated from their plasmid backbones by digestion with the stated restriction enzymes. DNA fragments were recovered from 0.7% TAE agarose gel slices using GeneClean II or GeneClean Spin Column Kits (Bio101) and Elutip-d columns (Schleicher and Schuell), and resuspended in injection buffer (10 mM Tris-HCl pH 7.5, 0.2 mM EDTA). DNA concentration was determined by comparison with DNA standards run on agarose gels, and the injection fragment was diluted to 0.5-1 ng/μl in injection buffer. The diluted DNA was prespun for 20 minutes and aliquots removed for microinjection into fertilized FVB mouse eggs. Injected eggs were transferred into recipient CD1 female animals. 15.5 days post-injection, fetal mice were dissected and DNA extracted from head tissue while the fetal livers were saved frozen in two halves for future analysis. Head DNA was extracted by Proteinase K digestion overnight, a single phenol/chloroform extraction and isopropanol precipitation. Transient transgenic fetuses were identified by slot blot hybridization with the 5′HS3 probe using standard procedures.

DNA Analysis

Southern transfer and hybridization were by standard procedures. Cop-number determination was performed using a Molecular Dynamics PhosphorImager. Single-copy animals showed a single random sized end-fragment in BamH1 and EcoR1 digests hybridized with the 5′HS3, βivs2 or Aγ-globin 3′ probes. With multicopy animals, the intensity of the end-fragment was defined as one transgene copy, and was used to calculate the copy number of the multicopy junction-fragment in the same lane. The intactness of the transgene in the DNA sample was verified by Southern blot analysis using two sets of digests, one for 5′ intactness and one for 3′ intactness, appropriate for each construct. The resulting fragments were hybridized to either βivs2, 5′HS3, or Aγ-globin 3′ probes. Mice that were mosaic for the transgene were excluded from the study by demonstration of insignificant transgene contribution to the fetal liver by Southern blot analysis of fetal liver DNA.

RNA Analysis

Fetal liver (embryonic day 15.5) RNA was extracted using Trizol Reagent (Gibco BRL), 1 μg was hybridized to [γATP]-labeled double-stranded 5′DNA probe for human β-globin detection or a [αdATP]-labeled double-stranded 3′ DNA probe for human Aγ-globin detection. A [γATP]-labeled double-stranded 5′DNA probe was used for mouse β-globin major detection used as a loading control. RNA/DNA hybrids were subsequently digested with 75 U S1 nuclease (Boehringer Mannheim) and run on a 6% sequencing gel as described [16]. Probe excess was demonstrated by including a sample containing 3 μg fetal liver RNA. Specific activities of human β-globin (Hβ) or human Aγ-globin (Hγ) relative to the mouse ,major (Mβ) probe is described for each S1 nuclease experiment in the corresponding figure legend. The protected 170 nt Hγ, 160 nt Hβ, and 95 nt Mβ bands were quantified on a Molecular Dynamics PhosphorImager and the % expression levels calculated according to the formula (Hβ or γ/Mβ)×100% and corrected for specific activity differences between the probe preparations. % Expression per transgene copy was calculated as (2 Mβ genes/number Hβ or γ transgenes)×(% expression)/(% transgenicity)×100%.

The present invention has been described in detail and with particular reference to the preferred embodiments; however, it will be understood by one having ordinary skill in the art that changes can be made thereto without departing from the spirit and scope of the invention.

All publications, patents and patent applications, including Canadian application no. 2,246,005, are incorporated by reference in their entirety to the same extent as if each individual publication, patent or patent application was specifically and individually indicated to be incorporated by reference in its entirety.

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4 1 3496 DNA Homo sapiens 1 cgatgaagct tcctcgaggc agaagagtca agcatttgcc taaggtcgga catgtcagag 60 gcagtgccag acctatgtga gactctgcag ctactgctca tgggccctgt gctgcactga 120 tgaggaggat cagatggatg gggcaatgaa gcaaaggaat cattctgtgg ataaaggaga 180 cagccatgaa gaagtctatg actgtaaatt tgggagcagg agtctctaag gacttggatt 240 tcaaggaatt ttgactcagc aaacacaaga ccctcacggt gactttgcga gctggtgtgc 300 cagatgtgtc tatcagaggt tccagggagg gtggggtggg gtcagggctg gccaccagct 360 atcagggccc agatgggtta taggctggca ggctcagata ggtggttagg tcaggttggt 420 ggtgctgggt ggagtccatg actcccagga gccaggagag atagaccatg agtagagggc 480 agacatggga aaggtggggg aggcacagca tagcagcatt tttcattcta ctactacatg 540 ggactgctcc cctatacccc cagctagggg caagtgcctt gactcctatg ttttcaggat 600 catcatctat aaagtaagag taataattgt gtctatctca tagggttatt atgaggatca 660 aaggagatgc acactctctg gaccagtggc ctaacagttc aggacagagc tatgggcttc 720 ctatgtatgg gtcagtggtc tcaatgtagc aggcaagttc cagaagatag catcaaccac 780 tgttagagat atactgccag tctcagagcc tgatgttaat ttagcaatgg gctgggaccc 840 tcctccagta gaaccttcta accagcctcg agggactagt cggtaccgtc gacaacctcc 900 tatttgacac cactgattac cccattgata gtcacacttt gggttgtaag tgacttttta 960 tttatttgta tttttgactg cattaagagg tctctagttt tttatctctt gtttcccaaa 1020 acctaataag taactaatgc acagagcaca ttgatttgta tttattctat ttttagacat 1080 aatttattag catgcatgag caaattaaga aaaacaacaa caaatgaatg catatatatg 1140 tatatgtatg tgtgtatata tacacatata tatatatatt ttttttcttt tcttaccaga 1200 aggttttaat ccaaataagg agaagatatg cttagaactg aggtagagtt ttcatccatt 1260 ctgtcctgta agtattttgc atattctgga gacgcaggaa gagatccatc tacatatccc 1320 aaagctgaat tatggtagac aaagctcttc cacttttagt gcatcaattt cttatttgtg 1380 taataagaaa attgggaaaa cgatcttcaa tatgcttacc aagctgtgat tccaaatatt 1440 acgtaaatac acttgcaaag gaggatgttt ttagtagcaa tttgtactga tggtatgggg 1500 ccaagagata tatcttagag ggagggctga gggtttgaag tccaactcct aagccagtgc 1560 cagaagagcc aaggacaggt acggctgtca tcacttagac ctcaccctgt ggagccacac 1620 cctagggttg gccaatctac tcccaggagc agggagggca ggagccaggg ctgggcataa 1680 aagtcagggc agagccatct attgcttaca tttgcttctg acacaactgt gttcactagc 1740 aacctcaaac agacacgatc ctgagaactt cagggtgagt ctatgggacc cttgatgttt 1800 tctttcccct tcttttctat ggttaagttc atgtcatagg aaggggagaa gtaacagggt 1860 acagtttaga atgggaaaca gacgaatgat tgcatcagtg tggaagtctc aggatcgttt 1920 tagtttcttt tatttgctgt tcataacaat tgttttcttt tgtttaattc ttgctttctt 1980 tttttttctt ctccgcaatt tttactatta tacttaatgc cttaacattg tgtataacaa 2040 aaggaaatat ctctgagata cattaagtaa cttaaaaaaa aactttacac agtctgccta 2100 gtacattact atttggaata tatgtgtgct tatttgcata ttcataatct ccctacttta 2160 ttttctttta tttttaattg atacataatc attatacata tttatgggtt aaagtgtaat 2220 gttttaatat gtgtacacat attgaccaaa tcagggtaat tttgcatttg taattttaaa 2280 aaatgctttc ttcttttaat atactttttt gtttatctta tttctaatac tttccctaat 2340 ctctttcttt cagggcaata atgatacaat gtatcatgcc tctttgcacc attctaaaga 2400 ataacagtga taatttctgg gttaaggcaa tagcaatatt tctgcatata aatatttctg 2460 catataaatt gtaactgatg taagaggttt catattgcta atagcagcta caatccagct 2520 accattctgc ttttatttta tggttgggat aaggctggat tattctgagt ccaagctagg 2580 cccttttgct aatcatgttc atacctctta tcttcctccc acagctcctg ggcaacgtgc 2640 tggtctgtgt gctggcccat cactttggca aagaattcac ccctgaggtg caggcttcct 2700 ggcagaagat ggtgactgca gtggccagtg ccctgtcctc cagataccac tgagcctctt 2760 gcccatgatt cagagctttc aaggataggc tttattctgc aagcaataca aataataaat 2820 ctattctgct gagagatcac acatgatttt cttcagctct tttttttaca tctttttaaa 2880 tatatgagcc acaaagggtt tatattgagg gaagtgtgta tgtgtatttc tgcatgcctg 2940 tttgtgtttg tggtgtgtgc atgctcctca tttattttta tatgagatgt gcattttgat 3000 gagcaaataa aagcagtaaa gacacttgta cacgggagtt ctgcaagtgg gagtaaatgg 3060 tgttggagaa atccggtggg aagaaagacc tctataggac aggacttctc agaaacagat 3120 gttttggaag agatgggaaa aggttcagtg aagacctggg ggctggattg attgcagctg 3180 agtagcaagg atggttctta atgaagggaa agtgttccag ctagcgtgct agtctcccgg 3240 aactatcact ctttcacagt ctgctttgga aggactgggc ttagtatgaa aagttaggac 3300 tgagaagaat ttgaaagggg gctttttgta gcttgatatt cactactgtc ttattaccct 3360 atcataggcc caccccaaat ggaagtccca ttcttcctca ggatgtttaa gattagcatt 3420 caggaagaga tcagaggtct gctggctccc ttatcatgtc ccttatggtg cttctggcta 3480 gcgatatcac cggtat 3496 2 3916 DNA Homo sapiens 2 cgatgaagct tcctcgaggc agaagagtca agcatttgcc taaggtcgga catgtcagag 60 gcagtgccag acctatgtga gactctgcag ctactgctca tgggccctgt gctgcactga 120 tgaggaggat cagatggatg gggcaatgaa gcaaaggaat cattctgtgg ataaaggaga 180 cagccatgaa gaagtctatg actgtaaatt tgggagcagg agtctctaag gacttggatt 240 tcaaggaatt ttgactcagc aaacacaaga ccctcacggt gactttgcga gctggtgtgc 300 cagatgtgtc tatcagaggt tccagggagg gtggggtggg gtcagggctg gccaccagct 360 atcagggccc agatgggtta taggctggca ggctcagata ggtggttagg tcaggttggt 420 ggtgctgggt ggagtccatg actcccagga gccaggagag atagaccatg agtagagggc 480 agacatggga aaggtggggg aggcacagca tagcagcatt tttcattcta ctactacatg 540 ggactgctcc cctatacccc cagctagggg caagtgcctt gactcctatg ttttcaggat 600 catcatctat aaagtaagag taataattgt gtctatctca tagggttatt atgaggatca 660 aaggagatgc acactctctg gaccagtggc ctaacagttc aggacagagc tatgggcttc 720 ctatgtatgg gtcagtggtc tcaatgtagc aggcaagttc cagaagatag catcaaccac 780 tgttagagat atactgccag tctcagagcc tgatgttaat ttagcaatgg gctgggaccc 840 tcctccagta gaaccttcta accagcctcg agggactagt cggtaccgtc gacaacctcc 900 tatttgacac cactgattac cccattgata gtcacacttt gggttgtaag tgacttttta 960 tttatttgta tttttgactg cattaagagg tctctagttt tttatctctt gtttcccaaa 1020 acctaataag taactaatgc acagagcaca ttgatttgta tttattctat ttttagacat 1080 aatttattag catgcatgag caaattaaga aaaacaacaa caaatgaatg catatatatg 1140 tatatgtatg tgtgtatata tacacatata tatatatatt ttttttcttt tcttaccaga 1200 aggttttaat ccaaataagg agaagatatg cttagaactg aggtagagtt ttcatccatt 1260 ctgtcctgta agtattttgc atattctgga gacgcaggaa gagatccatc tacatatccc 1320 aaagctgaat tatggtagac aaagctcttc cacttttagt gcatcaattt cttatttgtg 1380 taataagaaa attgggaaaa cgatcttcaa tatgcttacc aagctgtgat tccaaatatt 1440 acgtaaatac acttgcaaag gaggatgttt ttagtagcaa tttgtactga tggtatgggg 1500 ccaagagata tatcttagag ggagggctga gggtttgaag tccaactcct aagccagtgc 1560 cagaagagcc aaggacaggt acggctgtca tcacttagac ctcaccctgt ggagccacac 1620 cctagggttg gccaatctac tcccaggagc agggagggca ggagccaggg ctgggcataa 1680 aagtcagggc agagccatct attgcttaca tttgcttctg acacaactgt gttcactagc 1740 aacctcaaac agacaccatg ggtcatttca cagaggagga caaggctact atcacaagcc 1800 tgtggggcaa ggtgaatgtg gaagatgctg gaggagaaac cctgggaagg taggctctgg 1860 tgaccaggac aagggaggga aggaaggacc ctgtgcctgg caaaagtcca ggtcgcttct 1920 caggatttgt ggcaccttct gactgtcaaa ctgttcttgt caatctcaca ggctcctggt 1980 tgtctaccca tggacccaga ggttctttga cagctttggc aacctgtcct ctgcctctgc 2040 catcatgggc aaccccaaag tcaaggcaca tggcaagaag gtgctgactt ccttgggaga 2100 tgccataaag cacctggatg atctcaaggg cacctttgcc cagctgagtg aactgcactg 2160 tgacaagctg catgtggatc ctgagaactt cagggtgagt ctatgggacc cttgatgttt 2220 tctttcccct tcttttctat ggttaagttc atgtcatagg aaggggagaa gtaacagggt 2280 acagtttaga atgggaaaca gacgaatgat tgcatcagtg tggaagtctc aggatcgttt 2340 tagtttcttt tatttgctgt tcataacaat tgttttcttt tgtttaattc ttgctttctt 2400 tttttttctt ctccgcaatt tttactatta tacttaatgc cttaacattg tgtataacaa 2460 aaggaaatat ctctgagata cattaagtaa cttaaaaaaa aactttacac agtctgccta 2520 gtacattact atttggaata tatgtgtgct tatttgcata ttcataatct ccctacttta 2580 ttttctttta tttttaattg atacataatc attatacata tttatgggtt aaagtgtaat 2640 gttttaatat gtgtacacat attgaccaaa tcagggtaat tttgcatttg taattttaaa 2700 aaatgctttc ttcttttaat atactttttt gtttatctta tttctaatac tttccctaat 2760 ctctttcttt cagggcaata atgatacaat gtatcatgcc tctttgcacc attctaaaga 2820 ataacagtga taatttctgg gttaaggcaa tagcaatatt tctgcatata aatatttctg 2880 catataaatt gtaactgatg taagaggttt catattgcta atagcagcta caatccagct 2940 accattctgc ttttatttta tggttgggat aaggctggat tattctgagt ccaagctagg 3000 cccttttgct aatcatgttc atacctctta tcttcctccc acagctcctg ggcaacgtgc 3060 tggtctgtgt gctggcccat cactttggca aagaattcac ccctgaggtg caggcttcct 3120 ggcagaagat ggtgactgca gtggccagtg ccctgtcctc cagataccac tgagcctctt 3180 gcccatgatt cagagctttc aaggataggc tttattctgc aagcaataca aataataaat 3240 ctattctgct gagagatcac acatgatttt cttcagctct tttttttaca tctttttaaa 3300 tatatgagcc acaaagggtt tatattgagg gaagtgtgta tgtgtatttc tgcatgcctg 3360 tttgtgtttg tggtgtgtgc atgctcctca tttattttta tatgagatgt gcattttgat 3420 gagcaaataa aagcagtaaa gacacttgta cacgggagtt ctgcaagtgg gagtaaatgg 3480 tgttggagaa atccggtggg aagaaagacc tctataggac aggacttctc agaaacagat 3540 gttttggaag agatgggaaa aggttcagtg aagacctggg ggctggattg attgcagctg 3600 agtagcaagg atggttctta atgaagggaa agtgttccag ctagcgtgct agtctcccgg 3660 aactatcact ctttcacagt ctgctttgga aggactgggc ttagtatgaa aagttaggac 3720 tgagaagaat ttgaaagggg gctttttgta gcttgatatt cactactgtc ttattaccct 3780 atcataggcc caccccaaat ggaagtccca ttcttcctca ggatgtttaa gattagcatt 3840 caggaagaga tcagaggtct gctggctccc ttatcatgtc ccttatggtg cttctggcta 3900 gcgatatcac cggtat 3916 3 3385 DNA Homo sapiens 3 cgatgaagct tcctcgaggc agaagagtca agcatttgcc taaggtcgga catgtcagag 60 gcagtgccag acctatgtga gactctgcag ctactgctca tgggccctgt gctgcactga 120 tgaggaggat cagatggatg gggcaatgaa gcaaaggaat cattctgtgg ataaaggaga 180 cagccatgaa gaagtctatg actgtaaatt tgggagcagg agtctctaag gacttggatt 240 tcaaggaatt ttgactcagc aaacacaaga ccctcacggt gactttgcga gctggtgtgc 300 cagatgtgtc tatcagaggt tccagggagg gtggggtggg gtcagggctg gccaccagct 360 atcagggccc agatgggtta taggctggca ggctcagata ggtggttagg tcaggttggt 420 ggtgctgggt ggagtccatg actcccagga gccaggagag atagaccatg agtagagggc 480 agacatggga aaggtggggg aggcacagca tagcagcatt tttcattcta ctactacatg 540 ggactgctcc cctatacccc cagctagggg caagtgcctt gactcctatg ttttcaggat 600 catcatctat aaagtaagag taataattgt gtctatctca tagggttatt atgaggatca 660 aaggagatgc acactctctg gaccagtggc ctaacagttc aggacagagc tatgggcttc 720 ctatgtatgg gtcagtggtc tcaatgtagc aggcaagttc cagaagatag catcaaccac 780 tgttagagat atactgccag tctcagagcc tgatgttaat ttagcaatgg gctgggaccc 840 tcctccagta gaaccttcta accagcctcg agggactagt cggtaccgat ttatttcaaa 900 taggtacgga taagtagata ttgaggtaag cattaggtct tatattatgt aacactaatc 960 tattactgcg ctgaaactgt ggtctttatg aaaattgttt tcactacact attgagaaat 1020 taagagataa tggcaaaagt cacaaagagt atattcaaaa agaagtatag cactttttcc 1080 ttagaaacca ctgctaactg aaagagacta agatttgtcc cgtcaaaaat cctggaccta 1140 tgcctaaaac acatttcaca atccctgaac ttttcaaaaa ttggtacatg ctttagcttt 1200 aaactacagg cctcactgga gctacagaca agaaggtaaa aaacggctga caaaagaagt 1260 cctggtatcc tctatgatgg gagaaggaaa ctagctaaag ggaagaataa attagagaaa 1320 aactggaatg actgaatcgg aacaaggcaa aggctataaa aaaaattaag cagcagtatc 1380 ctcttggggg ccccttcccc acactatctc aatgcaaata tctgtctgaa acggtccctg 1440 gctaaactcc acccatgggt tggccagcct tgccttgacc aatagccttg acaaggcaaa 1500 cttgaccaat agtcttagag tatccagtga ggccaggggc cggcggctgg ctagggatga 1560 agaataaaag gaagcaccct tcagcagttc cacacactcg cttctggaac gtctgagatt 1620 atcaataagc tcctagtcca gacgcgatcc tgagaacttc agggtgagtc tatgggaccc 1680 ttgatgtttt ctttcccctt cttttctatg gttaagttca tgtcatagga aggggagaag 1740 taacagggta cagtttagaa tgggaaacag acgaatgatt gcatcagtgt ggaagtctca 1800 ggatcgtttt agtttctttt atttgctgtt cataacaatt gttttctttt gtttaattct 1860 tgctttcttt ttttttcttc tccgcaattt ttactattat acttaatgcc ttaacattgt 1920 gtataacaaa aggaaatatc tctgagatac attaagtaac ttaaaaaaaa actttacaca 1980 gtctgcctag tacattacta tttggaatat atgtgtgctt atttgcatat tcataatctc 2040 cctactttat tttcttttat ttttaattga tacataatca ttatacatat ttatgggtta 2100 aagtgtaatg ttttaatatg tgtacacata ttgaccaaat cagggtaatt ttgcatttgt 2160 aattttaaaa aatgctttct tcttttaata tacttttttg tttatcttat ttctaatact 2220 ttccctaatc tctttctttc agggcaataa tgatacaatg tatcatgcct ctttgcacca 2280 ttctaaagaa taacagtgat aatttctggg ttaaggcaat agcaatattt ctgcatataa 2340 atatttctgc atataaattg taactgatgt aagaggtttc atattgctaa tagcagctac 2400 aatccagcta ccattctgct tttattttat ggttgggata aggctggatt attctgagtc 2460 caagctaggc ccttttgcta atcatgttca tacctcttat cttcctccca cagctcctgg 2520 gcaacgtgct ggtctgtgtg ctggcccatc actttggcaa agaattcacc cctgaggtgc 2580 aggcttcctg gcagaagatg gtgactgcag tggccagtgc cctgtcctcc agataccact 2640 gagcctcttg cccatgattc agagctttca aggataggct ttattctgca agcaatacaa 2700 ataataaatc tattctgctg agagatcaca catgattttc ttcagctctt ttttttacat 2760 ctttttaaat atatgagcca caaagggttt atattgaggg aagtgtgtat gtgtatttct 2820 gcatgcctgt ttgtgtttgt ggtgtgtgca tgctcctcat ttatttttat atgagatgtg 2880 cattttgatg agcaaataaa agcagtaaag acacttgtac acgggagttc tgcaagtggg 2940 agtaaatggt gttggagaaa tccggtggga agaaagacct ctataggaca ggacttctca 3000 gaaacagatg ttttggaaga gatgggaaaa ggttcagtga agacctgggg gctggattga 3060 ttgcagctga gtagcaagga tggttcttaa tgaagggaaa gtgttccagc tagcgtgcta 3120 gtctcccgga actatcactc tttcacagtc tgctttggaa ggactgggct tagtatgaaa 3180 agttaggact gagaagaatt tgaaaggggg ctttttgtag cttgatattc actactgtct 3240 tattacccta tcataggccc accccaaatg gaagtcccat tcttcctcag gatgtttaag 3300 attagcattc aggaagagat cagaggtctg ctggctccct tatcatgtcc cttatggtgc 3360 ttctggctag cgatatcacc ggtat 3385 4 3805 DNA Homo sapiens 4 cgatgaagct tcctcgaggc agaagagtca agcatttgcc taaggtcgga catgtcagag 60 gcagtgccag acctatgtga gactctgcag ctactgctca tgggccctgt gctgcactga 120 tgaggaggat cagatggatg gggcaatgaa gcaaaggaat cattctgtgg ataaaggaga 180 cagccatgaa gaagtctatg actgtaaatt tgggagcagg agtctctaag gacttggatt 240 tcaaggaatt ttgactcagc aaacacaaga ccctcacggt gactttgcga gctggtgtgc 300 cagatgtgtc tatcagaggt tccagggagg gtggggtggg gtcagggctg gccaccagct 360 atcagggccc agatgggtta taggctggca ggctcagata ggtggttagg tcaggttggt 420 ggtgctgggt ggagtccatg actcccagga gccaggagag atagaccatg agtagagggc 480 agacatggga aaggtggggg aggcacagca tagcagcatt tttcattcta ctactacatg 540 ggactgctcc cctatacccc cagctagggg caagtgcctt gactcctatg ttttcaggat 600 catcatctat aaagtaagag taataattgt gtctatctca tagggttatt atgaggatca 660 aaggagatgc acactctctg gaccagtggc ctaacagttc aggacagagc tatgggcttc 720 ctatgtatgg gtcagtggtc tcaatgtagc aggcaagttc cagaagatag catcaaccac 780 tgttagagat atactgccag tctcagagcc tgatgttaat ttagcaatgg gctgggaccc 840 tcctccagta gaaccttcta accagcctcg agggactagt cggtaccgat ttatttcaaa 900 taggtacgga taagtagata ttgaggtaag cattaggtct tatattatgt aacactaatc 960 tattactgcg ctgaaactgt ggtctttatg aaaattgttt tcactacact attgagaaat 1020 taagagataa tggcaaaagt cacaaagagt atattcaaaa agaagtatag cactttttcc 1080 ttagaaacca ctgctaactg aaagagacta agatttgtcc cgtcaaaaat cctggaccta 1140 tgcctaaaac acatttcaca atccctgaac ttttcaaaaa ttggtacatg ctttagcttt 1200 aaactacagg cctcactgga gctacagaca agaaggtaaa aaacggctga caaaagaagt 1260 cctggtatcc tctatgatgg gagaaggaaa ctagctaaag ggaagaataa attagagaaa 1320 aactggaatg actgaatcgg aacaaggcaa aggctataaa aaaaattaag cagcagtatc 1380 ctcttggggg ccccttcccc acactatctc aatgcaaata tctgtctgaa acggtccctg 1440 gctaaactcc acccatgggt tggccagcct tgccttgacc aatagccttg acaaggcaaa 1500 cttgaccaat agtcttagag tatccagtga ggccaggggc cggcggctgg ctagggatga 1560 agaataaaag gaagcaccct tcagcagttc cacacactcg cttctggaac gtctgagatt 1620 atcaataagc tcctagtcca gacgccatgg gtcatttcac agaggaggac aaggctacta 1680 tcacaagcct gtggggcaag gtgaatgtgg aagatgctgg aggagaaacc ctgggaaggt 1740 aggctctggt gaccaggaca agggagggaa ggaaggaccc tgtgcctggc aaaagtccag 1800 gtcgcttctc aggatttgtg gcaccttctg actgtcaaac tgttcttgtc aatctcacag 1860 gctcctggtt gtctacccat ggacccagag gttctttgac agctttggca acctgtcctc 1920 tgcctctgcc atcatgggca accccaaagt caaggcacat ggcaagaagg tgctgacttc 1980 cttgggagat gccataaagc acctggatga tctcaagggc acctttgccc agctgagtga 2040 actgcactgt gacaagctgc atgtggatcc tgagaacttc agggtgagtc tatgggaccc 2100 ttgatgtttt ctttcccctt cttttctatg gttaagttca tgtcatagga aggggagaag 2160 taacagggta cagtttagaa tgggaaacag acgaatgatt gcatcagtgt ggaagtctca 2220 ggatcgtttt agtttctttt atttgctgtt cataacaatt gttttctttt gtttaattct 2280 tgctttcttt ttttttcttc tccgcaattt ttactattat acttaatgcc ttaacattgt 2340 gtataacaaa aggaaatatc tctgagatac attaagtaac ttaaaaaaaa actttacaca 2400 gtctgcctag tacattacta tttggaatat atgtgtgctt atttgcatat tcataatctc 2460 cctactttat tttcttttat ttttaattga tacataatca ttatacatat ttatgggtta 2520 aagtgtaatg ttttaatatg tgtacacata ttgaccaaat cagggtaatt ttgcatttgt 2580 aattttaaaa aatgctttct tcttttaata tacttttttg tttatcttat ttctaatact 2640 ttccctaatc tctttctttc agggcaataa tgatacaatg tatcatgcct ctttgcacca 2700 ttctaaagaa taacagtgat aatttctggg ttaaggcaat agcaatattt ctgcatataa 2760 atatttctgc atataaattg taactgatgt aagaggtttc atattgctaa tagcagctac 2820 aatccagcta ccattctgct tttattttat ggttgggata aggctggatt attctgagtc 2880 caagctaggc ccttttgcta atcatgttca tacctcttat cttcctccca cagctcctgg 2940 gcaacgtgct ggtctgtgtg ctggcccatc actttggcaa agaattcacc cctgaggtgc 3000 aggcttcctg gcagaagatg gtgactgcag tggccagtgc cctgtcctcc agataccact 3060 gagcctcttg cccatgattc agagctttca aggataggct ttattctgca agcaatacaa 3120 ataataaatc tattctgctg agagatcaca catgattttc ttcagctctt ttttttacat 3180 ctttttaaat atatgagcca caaagggttt atattgaggg aagtgtgtat gtgtatttct 3240 gcatgcctgt ttgtgtttgt ggtgtgtgca tgctcctcat ttatttttat atgagatgtg 3300 cattttgatg agcaaataaa agcagtaaag acacttgtac acgggagttc tgcaagtggg 3360 agtaaatggt gttggagaaa tccggtggga agaaagacct ctataggaca ggacttctca 3420 gaaacagatg ttttggaaga gatgggaaaa ggttcagtga agacctgggg gctggattga 3480 ttgcagctga gtagcaagga tggttcttaa tgaagggaaa gtgttccagc tagcgtgcta 3540 gtctcccgga actatcactc tttcacagtc tgctttggaa ggactgggct tagtatgaaa 3600 agttaggact gagaagaatt tgaaaggggg ctttttgtag cttgatattc actactgtct 3660 tattacccta tcataggccc accccaaatg gaagtcccat tcttcctcag gatgtttaag 3720 attagcattc aggaagagat cagaggtctg ctggctccct tatcatgtcc cttatggtgc 3780 ttctggctag cgatatcacc ggtat 3805 

We claim:
 1. A hybrid nucleic acid molecule that when integrated into the genome at single gene copy produces an RNA encoding a polypeptide in a targeted mammalian cell of the erythroid lineage, comprising: i) globin nucleic acid regulatory elements comprising a) a β-globin 5′HS3, b) a β-globin promoter or an Aγ-globin promoter, c) a β-globin intron 2, d) a β-globin 3′ enhancer; and ii) a β-globin coding nucleic acid molecule operatively associated with the regulatory elements and capable of expression in the cell.
 2. The hybrid nucleic acid molecule of claim 1, wherein the mammalian cell is a human cell.
 3. A vector comprising the nucleic acid molecule of claim
 1. 4. A composition comprising the vector of claim
 3. 5. An isolated host cell comprising the vector of claim
 3. 6. The host cell of claim 5, wherein the host cell is a cell of the erythroid lineage selected from the group consisting of: an erythroid cell, an erythroid cell precursor, a bone marrow cell, an umbilical cord blood cell, a hematopoietic stem cell, a hematopoietic stem cell that is CD34−/CD38−, or CD34+/CD38−, a progenitor cell of the erythroid lineage, CFU-GEMM, BFU-E, CFU-E, a pro-erythroblast an erythroblast and an erythrocyte.
 7. A method for expressing a nucleic acid molecule in a mammalian cell of the erythroid lineage in vitro, comprising a) administering to the cell an effective amount of the hybrid nucleic acid molecule of claim 1 so that the hybrid nucleic acid molecule is inserted into the genome at single gene copy and b) expressing the nucleic acid molecule to produce a γ-globin RNA and its encoded polypeptide.
 8. A method for producing γ-globin polypeptide in a mammalian cell of the erythroid lineage in vitro, comprising a) administering to the cell an effective amount of the hybrid nucleic acid molecule of claim 1 so that the hybrid nucleic acid molecule is inserted into the genome at single gene copy and b) expressing the nucleic acid molecule to produce γ-globin RNA and its encoded polypeptide.
 9. The hybrid nucleic acid molecule of claim 1, comprising all or part of a nucleic acid molecule selected from the group consisting of: a) SEQ ID NO:1, SEQ ID NO:2, SEQ ID NO:3, and SEQ ID NO:4, or complements thereof.
 10. The hybrid nucleic acid molecule of claim 1, wherein the molecule hybridizes to a nucleic acid molecule of any one of SEQ ID NO:1 to SEQ ID NO:4, or a complement thereof under high stringency hybridization conditions comprising 0.2% SSC and a temperature of 65° C., the nucleic acid molecule producing an RNA encoding a polypeptide in a targeted mammalian cell of the erythroid lineage when the nucleic acid molecule is integrated into the genome at single gene copy.
 11. The hybrid nucleic acid molecule of claim 1, wherein the β-globin 5′HS3 comprises all or part of nucleotide nos. 28-882 of SEQ ID NO:2, the β-globin promoter comprises all or part of nucleotide nos. 903-1771 SEQ ID NO:2, the β-globin intron 2 comprises all or part of nucleotide nos. 2191-3108 of SEQ ID NO:2 and the β-globin 3′ enhancer comprises all or part of nucleotide nos. 3655-3912 of SEQ ID NO:2.
 12. The hybrid nucleic acid molecule of claim 1, wherein the β-globin 5′HS3 comprises all or part of nucleotide nos. 23-877 of SEQ ID NO:4, the Aγ-globin promoter comprises all or part of nucleotide nos. 896-1655 SEQ ID NO:4, the β-globin intron 2 comprises all or part of nucleotide nos. 2075-2992 of SEQ ID NO:4 and the β-globin 3′ enhancer comprises all or part of nucleotide nos. 3539-3796 of SEQ ID NO:4.
 13. A nucleic acid molecule having at least about 97% identity with the nucleic acid molecule of any one of SEQ ID NO:1 to SEQ ID NO:4, or a complement thereof, the nucleic acid molecule producing an RNA encoding a polypeptide in a targeted mammalian cell of the erythroid lineage when the nucleic acid molecule is integrated into the genome at single gene copy, wherein the nucleic acid molecule comprises globin nucleic acid regulatory elements: (a) a β-globin 5′HS3; (b) a β-globin intron 2 and (c) a β-globin 3′enhancer.
 14. The nucleic acid molecule of claim 13 which further comprises a β-globin promoter or an Aγ-globin promoter.
 15. A hybrid nucleic acid molecule that when integrated into the genome at single gene copy produces an RNA encoding a polypeptide in a targeted mammalian cell of the erythroid lineage, comprising globin regulatory elements having at least 90% sequence identity to the globin regulatory elements selected from the group consisting of a β-globin promoter comprising nucleotide nos. 903-1771 of SEQ ID NO:2 and Aγ-globin promoter comprising nucleotide nos. 896-1655 of SEQ ID NO:4, and having at least 97% sequence identity to globin nucleic acid regulatory elements: (a) a β-globin 5′HS3 comprising 28-882 of SEQ ID NO:2 or 23-887 of SEQ ID NO:4; (b) a β-globin intron 2 comprising nucleotide nos. 2191-3108 of SEQ ID NO:2 or 2075-2002 of SEQ ID NO:4 and (c) a β-globin 3′ enhancer comprising nucleotide nos. 3655-3912 of SEQ ID NO:2 or 3539-3796 of SEQ ID NO:4, wherein the nucleic acid molecule comprises the following globin nucleic acid regulatory elements:(a) a β-globin 5′HS3; (b) a β-globin intron 2; (c) a β-globin 3′ enhancer; (d) a promoter selected from the group consisting of a β-globin promoter and a Aγ-globin promoter.
 16. A hybrid nucleic acid molecule that when integrated into the genome at single gene copy produces an RNA encoding a polypeptide a targeted mammalian cell of the erythroid lineage, comprising globin regulatory elements having at least 95% sequence identity to the globin regulatory elements selected from the group consisting of a (-globin promoter comprising nucleotide nose 903-1771 of SEQ ID NO:2 and Aγ-globin promoter comprising nucleotide nos. 896-1655 of SEQ ID NO:4, and having at least 97% sequence identity to β-globin nucleic acid regulatory elements: (a) a 5′HS3 comprising 28-882 of SEQ ID NO:2 or 23-887 of SEQ ID NO:4; (b) a β-globin intron 2 comprising nucleotide nos. 2191-3108 of SEQ ID NO:2 or 2075-2002 of SEQ ID NO:4 and (c) a β-globin 3′ enhancer comprising nucleotide nos. 3655-3912 of SEQ ID NO:2 or 3539-3796 of SEQ ID NO:4, wherein the nucleic acid molecule comprises the following globin nucleic acid regulatory elements: (a) a β-globin 5′HS3; (b) a β-globin intron 2; (c) a β-globin 3′ enhancer; (d) a promoter selected from the group consisting of a β-globin promoter and a Aγ-globin promoter. 